Radio communication base station apparatus and report channel signal transmission band setting method

ABSTRACT

Provided is a base station capable of effectively transmitting BCH data. The base station ( 100 ) includes: an encoding unit ( 101 ) for encoding the BCH data; a modulation unit ( 102 ) for modulating the BCH data after being encoded; a transmission band setting unit ( 103 ) for setting a BCH data transmission band in one of sub carriers constituting an OFDM symbol; encoding units ( 104 - 1  to  104 -N) for encoding user data (# 1  to #N), modulation units ( 105 - 1  to  105 -N) for modulating user data (# 1  to #N) after being encoded; and an IFFT unit ( 106 ) for mapping the BCH data and the user data (# 1  to #N) to each of the sub carriers (# 1  to #K) and performing IFFT to generate an OFDM symbol. Here, the IFFT unit ( 106 ) maps the BCH data to the sub carrier existing in the transmission band set by the transmission band setting unit ( 103 ) among the plurality of sub carriers (# 1  to #K).

TECHNICAL FIELD

The present invention relates to a radio communication base stationapparatus and a method for setting a transmission band for a broadcastchannel signal.

BACKGROUND ART

In recent years, in radio communication, particularly in mobilecommunication, various kinds of information such as images and dataother than speech have become targets of transmission. In the future,there will be a growing demand for transmission of various content, andso there will be a growing need for high speed transmission. However,when high speed transmission is performed in mobile communication, theinfluence of delay waves due to multipath cannot be ignored, andtransmission characteristics degrade due to frequency selective fading.

As one of the techniques for combating frequency selective fading,attention is focused on multicarrier communication such as OFDM(Orthogonal Frequency Division Multiplexing). Multicarrier communicationtransmits data using a plurality of carriers (subcarriers) with thetransmission rate lowered to a degree not causing frequency selectivefading, and thereby performs high speed transmission. Particularly, inthe OFDM scheme, a plurality of subcarriers where data is arranged areorthogonal to each other, and so high frequency efficiency can beachieved among multicarrier communication. Further, the OFDM scheme canbe realized using a relatively simple hardware configuration, and soattention is focused on the OFDM scheme particularly, and various studyis underway.

In the 3GPP LTE standardization, study is underway to make it possibleto use a plurality of radio communication mobile station apparatuses(hereinafter abbreviated as “mobile stations”) with different frequencybandwidths (hereinafter abbreviated as “bandwidths”) in a mobilecommunication system of the OFDM scheme. Such a mobile communicationsystem is often referred to as a “scalable bandwidth communicationsystem.” For example, in a scalable bandwidth communication systemhaving a frequency band (hereinafter abbreviated as “band”) of 20 MHz, amobile station capable of communicating at one of 5 MHz, 10 MHz and 20MHz, can be used. Hereinafter, a mobile station capable of communicatingat 5 MHz, a mobile station capable of communicating at 10 MHz and amobile station capable of communicating at 20 MHz are referred to as a“5 MHz mobile station,” “10 MHz mobile station” and “20 MHz mobilestation,” respectively. Further, out of the three types of mobilestations that can be used, a mobile station with the minimumcommunication capability is referred to as a “minimum capability mobilestation.” Therefore, in this case, the 5 MHz mobile station is theminimum capability mobile station. In such a scalable bandwidthcommunication system, the 5 MHz mobile station is assigned a 5 MHzbandwidth in the 20 MHz band and performs communication. Further, the 20MHz mobile station can perform communication using the whole of the 20MHz band and so can perform communication at higher speed.

On the other hand, in a mobile communication system adopting thecellular scheme, a radio communication base station apparatus(hereinafter abbreviated as “base station”) broadcasts per cell,information required for communicating user data, to all the mobilestations in the cell. This broadcast information is transmitted using aBCH (Broadcast CHannel). The BCH is one of common control channels indownlink and transmits broadcast information such as system information,cell information and transmission parameters, and the like. Thebroadcast information transmitted using the BCH is hereinafter referredto as “BCH data.” Mobile stations receive BCH data upon poweractivation, learn system information, cell information, transmissionparameters, and the like, and then start communicating user data.Further, the transmission parameters such as frame formats are updatedover time, and so mobile stations need to receive BCH data even whilecommunicating user data.

As a method for transmitting BCH data in the above-described scalablebandwidth communication system, as shown in the upper part of FIG. 1,transmitting BCH data using the center frequency band (1.25 MHzbandwidth) of 20 MHz band, is proposed (see Non-Patent Document 1). Asshown in the upper part of FIG. 1, in this scalable bandwidthcommunication system, in accordance with a bandwidth (5 MHz) in whichthe minimum capability mobile station can perform communication, a 20MHz band is equally divided into four bands FB1 to FB4 per 5 MHzbandwidth. The minimum capability mobile station is assigned one of thebands FB1 to FB4 and communicates user data. Here, one frame is 10 msand is comprised of 20 subframes. BCH data is transmitted once per oneframe using one of the subframes. Further, the content of BCH data isupdated in a relatively long cycle of approximately 100 frames.Non-Patent Document 1: 3GPP RAN WG1 Ad Hoc on LTE meeting (2005.06)R1-050590 “Physical Channels and Multiplexing in Evolved UTRA Downlink”

DISCLOSURE OF INVENTION Problems to be Solved by the Invention

As described above, the minimum capability mobile station is assignedone of the bands FB1 to FB4 and communicates user data. Therefore, asshown in the lower part of FIG. 1, to receive BCH data while receivinguser data, the minimum capability mobile station assigned with, forexample, FB1, has to switch the reception frequency while receiving userdata. That is, the minimum capability mobile station that communicatesuser data using FB1, needs to switch the reception frequency from FB1for receiving user data, to the center frequency band (1.25 MHzbandwidth) of 20 MHz band to receive BCH data, and, then switch thereception frequency from the center frequency to FB1 again to receiveuser data. This switching of the reception frequency requires time ofapproximately one subframe each, and so the minimum capability mobilestation cannot receive user data in three subframes. Therefore, userthroughput decreases.

Further, when all the mobile stations switch the reception frequency atthe same time to receive BCH data, the base station cannot transmit userdata at all in the meantime (in three subframes). Therefore, the systemthroughput decreases.

Further, the minimum capability mobile station needs to switch thereception frequency to receive BCH data, and so the amount of processingat the mobile stations increases and power consumption also increases.

To solve these problems caused by the switching of reception frequency,as shown in FIG. 2, BCH data may be transmitted in every frame in allbands FB1 to FB4. However, this substantially reduces communicationresources that can be used for user data.

Therefore, as shown in FIG. 3, intervals for transmitting BCH data maybe extended compared to those in FIG. 2. However, BCH data is stilltransmitted at the same timing in all bands FB1 to FB4, and so peakpower of BCH data becomes large. Peak power becomes extremely large inBCH data which is transmitted with large power so as to be received atthe mobile station located at the cell boundary. Such an increase inpeak power causes distortion of the transmission signal and degradeserror rate performances. To prevent degradation of error rateperformances, the base station needs to have a high-performanceamplifier with a large linear region, and, as a result, cost formanufacturing a base station increases.

It is therefore an object of the present invention to provide a basestation that can solve the above problems and transmit BCH dataefficiently and a method for setting a transmission band for a broadcastchannel signal.

Means for Solving the Problem

The base station of the present invention transmits a multicarriersignal comprised of a plurality of subcarriers, and has: a settingsection that sets a transmission band for a broadcast channel signal toone of a plurality of first frequency bands in a second frequency band,the second frequency band being divided into the plurality of firstfrequency bands per bandwidth in which a radio communication mobilestation apparatus with a minimum capability can perform communication; agenerating section that generate the multicarrier signal by mapping thebroadcast channel signal on subcarriers in the transmission band set bythe setting section out of the plurality of subcarriers; and atransmitting section that transmits the multicarrier signal to the radiocommunication mobile station apparatus, and in the base station, thesetting section changes over time the first frequency band in which thetransmission band is set in the second frequency band.

Advantageous Effect of the Invention

According to the present invention, it is possible to transmit BCH dataefficiently.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 shows a conventional method for transmitting BCH data;

FIG. 2 shows example 1 for solving the problem of the conventionalmethod for transmitting BCH data;

FIG. 3 shows example 2 for solving the problem of the conventionalmethod for transmitting BCH data;

FIG. 4 is a block diagram showing the configuration of a base stationaccording to Embodiment 1 of the present invention;

FIG. 5 shows an example of an OFDM symbol according to Embodiment 1 ofthe present invention;

FIG. 6 shows a method for transmitting BCH data according to Embodiment1 of the present invention;

FIG. 7 is a block diagram showing the configuration of a base stationaccording to Embodiment 2 of the present invention;

FIG. 8 shows a method for transmitting BCH data according to Embodiment2 of the present invention;

FIG. 9 is a block diagram showing the configuration of a base stationaccording to Embodiment 3 of the present invention;

FIG. 10 shows a method for transmitting BCH data according to Embodiment3 of the present invention;

FIG. 11 shows a method for transmitting BCH data (in adjacent cell #2)according to Embodiment 4 of the present invention;

FIG. 12 shows a method for transmitting BCH data (in adjacent cell #3)according to Embodiment 4 of the present invention;

FIG. 13 is a block diagram showing the configuration of a base stationaccording to Embodiment 5 of the present invention;

FIG. 14 shows a method for transmitting BCH data according to Embodiment5 of the present invention;

FIG. 15 shows another method for transmitting BCH data according toEmbodiment 5 of the present invention;

FIG. 16 shows still another method for transmitting BCH data accordingto Embodiment 5 of the present invention;

FIG. 17 shows yet another method for transmitting BCH data according toEmbodiment 5 of the present invention;

FIG. 18 shows a method for transmitting scheduling information accordingto Embodiment 6 of the present invention;

FIG. 19 is a block diagram showing the configuration of a base stationaccording to Embodiment 6 of the present invention;

FIG. 20 shows a method for transmitting scheduling information accordingto Embodiment 7 of the present invention; and

FIG. 21 is a block diagram showing the configuration of a base stationaccording to Embodiment 7 of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION

Embodiments of the present invention will be described in detail belowwith reference to the accompanying drawings. Although the OFDM schemewill be described as an example of a multicarrier communication schemein the following description, the present invention is not limited tothe OFDM scheme.

Embodiment 1

FIG. 4 shows the configuration of base station 100 according to thepresent embodiment.

Encoding section 101 encodes BCH data.

Modulating section 102 modulates the encoded BCH data.

Transmission band setting section 103 sets BCH data transmission band.Transmission band setting section 103 sets the BCH data transmissionband to one of a plurality of subcarriers forming an OFDM symbol, whichis a multicarrier signal. This transmission band setting will bedescribed in detail below.

Encoding sections 104-1 to 104-N and modulating sections 105-1 to 105-Nare provided so as to support mobile stations #1 to #N, respectively, towhich base station 100 transmits user data.

Encoding sections 104-1 to 104-N encode user data #1 to #N,respectively.

Modulating sections 105-1 to 105-N modulate encoded user data #1 to #N,respectively.

IFFT section 106 maps BCH data and user data #1 to #N on subcarriers #1to #K, performs an IFFT (Inverse Fast Fourier Transform) and generatesan OFDM symbol. IFFT section 106 maps the BCH data on subcarriers in thetransmission band set by transmission band setting section 103 out of aplurality of subcarriers #1 to #K.

The OFDM symbol generated in this way is subjected to predeterminedradio processing such as up-conversion in radio transmitting section 108after a cyclic prefix is added in CP adding section 107, and istransmitted by radio to mobile stations #1 to #N via antenna 109.

Next, the transmission band setting will be described in detail. Asshown in FIG. 5, one OFDM symbol is formed with subcarriers #1 to #16(K=16). Further, the bandwidth of this OFDM symbol is 20 MHz, and, inthe same way as described above, this 20 MHz band is equally dividedinto bands FB1 to FB4 per 5 MHz bandwidth in accordance with a bandwidth(5 MHz) in which the minimum capability mobile station can performcommunication. Further, the minimum capability mobile stationcommunicates user data using one of the bands FB1 to FB4.

Transmission band setting section 103 sets the BCH data transmissionband to one of the bands FB1 to FB4. Transmission band setting section103 changes the BCH data transmission band per frame. For example,transmission band setting section 103 sets the BCH data transmissionband to FB1 in frame #1, sets the band to FB2 in frame #2, sets the bandto FB3 in frame #3, and sets the band to FB4 in frame #4. Therefore, inthe case of this example, IFFT section 106 maps BCH data on one of thesubcarriers #1 to #4 included in FB1 in frame #1, maps BCH data on oneof the subcarriers #5 to #8 included in FB2 in frame #2, maps BCH dataon one of the subcarriers #9 to #12 included in FB3 in frame #3, andmaps BCH data on one of subcarriers #13 to #16 included in FB4 in frame#4. In this case, IFFT section 106 may map BCH data on one of thesubcarriers out of four subcarriers included in each of bands FB1 to FB4or map BCH data on a plurality of subcarriers. In this way, transmissionband setting section 103 changes over time, the band in which the BCHdata transmission band is set out of the four bands FB1 to FB4 in 20 MHzband.

This is shown in FIG. 6. As shown in this figure, the BCH datatransmission band is set to FB1 in frame #1, set to FB2 in frame #2, setto FB3 in frame #3, and set to FB4 in frame #4. In frame #5, the BCHdata transmission band is set to FB1 again. In this way, transmissionband setting section 103 changes over time, the band in which the BCHdata transmission band is set periodically. Although the band in whichthe BCH data transmission band is set is changed to FB1, FB2, FB3 andFB4, in order, the order of change is not limited to this order.Further, although the transmission band is changed per frame here, thetransmission band may be changed per each of a plurality of frames.

By setting the BCH data transmission band as described above, theminimum capability mobile station that communicates user data using, forexample, FB1, can receive BCH data in frames #1 and #5 without switchingthe reception frequency while receiving user data. The same applies tothe minimum capability mobile station that communicates user data usingone of FB2 to FB4. That is, the minimum capability mobile station canalways receive BCH data once every four frames without switching thereception frequency from that for receiving user data. In this way,according to the present embodiment, it is not necessary to switch thereception frequency to receive BCH data in the minimum capability mobilestation that communicates user data using one of the bands FB1 to FB4,so that it is possible to prevent a decrease in user throughput and adecrease in system throughput, which are caused by the switching of thereception frequency.

Furthermore, the minimum capability mobile station does not need toswitch the reception frequency to receive BCH data, so that it ispossible to eliminate power consumption for processing of switching thereception frequency.

Further, as described above, the content of BCH data is updated in arelatively long cycle of approximately 100 frames, so that, as shown inFIG. 2, it is not necessary to transmit BCH data in every frame in allbands FB1 to FB4, and transmitting BCH data once every four frames ineach band of FB1 to FB4 as described in the present embodiment, isenough. In this way, according to the present embodiment, compared tothe case shown in FIG. 2, the number of times BCH data is transmitted ineach band of FB1 to FB4 is reduced, so that it is possible to prevent adecrease in communication resources that can be used for user data.

Further, according to the present embodiment, BCH data is transmitted inone of the bands FB1 to FB4 in each frame and BCH data is nottransmitted at the same timing in all bands FB1 to FB4, so that it ispossible to prevent an increase in peak power of BCH data.

As described above, according to the present embodiment, it is possibleto transmit BCH data efficiently.

Embodiment 2

The base station according to the present embodiment reports thetransmission band for BCH data set by transmission band setting section103 to mobile stations using a synchronization channel signal.

FIG. 7 shows the configuration of base station 200 according to thepresent embodiment. In FIG. 7, components that are the same as those inEmbodiment 1 (FIG. 4) will be assigned the same reference numeralswithout further explanations.

Transmission timing controlling section 201 controls a timing fortransmitting BCH data. This transmission timing control will bedescribed in detail later.

Transmission band setting section 103 generates data for reporting theset the BCH data transmission band to mobile stations, that is, data forreporting which of bands FB1 to FB4 the transmission band is set to, tomobile stations (transmission band report data) and outputs the data asS-SCH (Secondary Synchronization CHannel) data. That is, thetransmission band report data is transmitted using an S-SCH in an SCH(Synchronization CHannel). The S-SCH may also transmit scrambling codeinformation and the like, in addition to the transmission band reportdata.

Encoding section 202 encodes S-SCH data.

Modulating section 203 modulates the encoded S-SCH data.

Further, data (P-SCH data) transmitted using a P-SCH (PrimarySynchronization CHannel) in the SCH is modulated at modulating section204. P-SCH data includes a sequence common to all cells, and thissequence is used for timing synchronization upon cell search.

IFFT section 106 maps SCH data formed with P-SCH data and S-SCH data,BCH data and user data #1 to #N on subcarriers #1 to #K, performs anIFFT and generates an OFDM symbol. In this case, IFFT section 106 mapsthe SCH data on a predetermined subcarrier out of subcarriers #1 to #16.Here, for example, IFFT section 106 maps the SCH data on eithersubcarrier #8 or #9, which is the center frequency band of the 20 MHzband.

Next, transmission timing control will be described in detail.

As shown in FIG. 8, transmission timing controlling section 201 sets thetiming for transmitting BCH data to timing Δt after the timing fortransmitting SCH data. Δt is time a mobile station takes to switch thereception frequency (frequency switching time). Therefore, by thistransmission timing control, radio transmitting section 108 transmits anOFDM symbol including BCH data at transmission timing Δt after a timingfor transmitting an OFDM symbol including SCH data. This SCH dataincludes the transmission band report data for the BCH data transmittedΔt after this SCH data. The switching of the reception frequency at themobile station normally requires time of approximately one subframe.

In this way, according to the present embodiment, transmission bandreport data is transmitted to mobile stations using an SCH, so that theminimum capability mobile station that is immediately after poweractivation and searching cell, detects the SCH and can receive BCH dataΔt after the detection of the SCH by switching the reception frequencyto the band shown in the transmission band report data after thedetection of the SCH. Further, by setting Δt as time a mobile stationtakes to switch the reception frequency, the minimum capability mobilestation can receive BCH data immediately after switching the receptionfrequency. Therefore, according to the present embodiment, even when BCHdata is transmitted as described in Embodiment 1, the minimum capabilitymobile station immediately after power activation can receive BCH dataupon power activation immediately after detecting the SCH, so that it ispossible to shorten the time until user data communication is started.

Embodiment 3

FIG. 9 shows the configuration of base station 300 according to thepresent embodiment. In FIG. 9, components that are the same as those inEmbodiment 1 (FIG. 4) will be assigned the same reference numeralswithout further explanations.

The mobile stations to which base station 300 transmits BCH data areroughly divided into mobile stations that are communicating user dataand mobile stations that are immediately after power activation and notcommunicating user data. A state where user data communication is inprogress may be referred to as “connected mode” or “active mode,” and astate where user data communication is not in progress may be referredto as “idle mode” or “inactive mode.” Further, connected mode may be astate after the mobile station is assigned a band for communicating userdata, and idle mode may be a state before the mobile station is assigneda band for communicating user data, such as standby mode.

In FIG. 9, BCH1 data is broadcast information required by mobilestations in connected mode, and, for example, includes subframeconfiguration information such as the arrangement of multicastsubframes, and mapping information such as the arrangement ofdistributed channels and localized channels. The transmission band isset for BCH1 data in the same way as in Embodiment 1.

On the other hand, BCH2 data is information required by mobile stationsin idle mode, and, for example, is mapping information for pagingchannels and RACH resource information.

Encoding section 301 encodes BCH2 data.

Modulating section 302 modulates the encoded BCH2 data.

IFFT section 106 maps the BCH1 data, the BCH2 data and user data #1 to#N on subcarriers #1 to #K, performs an IFFT and generates an OFDMsymbol. In this case, IFFT section 106 maps the BCH2 data on apredetermined subcarrier out of subcarriers #1 to #16. Here, forexample, IFFT section 106 maps the BCH2 data on either subcarrier #8 or#9, which is the center frequency band of 20 MHz band.

That is, as shown in FIG. 10, base station 300 transmits BCH1 dataincluding information required by mobile stations in connected mode inthe same way as in Embodiment 1, and transmits BCH2 data includinginformation required by mobile stations in idle mode, in every frameusing predetermined band (in FIG. 10, the center frequency band of 20MHz).

In this way, according to the present embodiment, while BCH1 data istransmitted in the same way as in Embodiment 1, BCH2 data is transmittedin every frame using predetermined band. Therefore, even when BCH1 datais transmitted as described in Embodiment 1, the mobile station in idlemode, immediately after power activation, can receive BCH2 data requiredupon power activation within one frame at a maximum, so that it ispossible to shorten time until user data communication is started.

Embodiment 4

In the present embodiment, a plurality of base stations in adjacentcells transmit BCH data in the same way as in Embodiment 1 and maketheir transmission patterns different from each other. For example,while transmission band setting section 103 in base station 100 (FIG. 4)in cell #1 sets the BCH data transmission band as shown in FIG. 6,transmission band setting section 103 in base station 100 in cell #2,which is an adjacent cell of cell #1, sets the BCH data transmissionband as shown in FIG. 11. Further, transmission band setting section 103in base station 100 in cell #3, which is an adjacent cell of cell #1 andcell #2, sets the BCH data transmission band as shown in FIG. 12.

When FIG. 6, FIG. 11 and FIG. 12 are compared, in any of frames #1 to#6, the base stations transmit BCH data in bands different from otherbase stations in adjacent cells. For example, in frame 1, base station100 in cell #1 transmits BCH data in band FB1, while base station 100 incell #2 transmits BCH data in band FB2, and base station 100 in cell #3transmits BCH data in band FB3.

In this way, according to the present embodiment, transmission bandsetting section 103 in base station 100 sets the BCH data transmissionband to a band different from the bands to which other base stations 100in the adjacent cells set the BCH data transmission bands.

Therefore, according to the present embodiment, it is possible to reducethe interference between the cells of the BCH data transmitted withlarge power.

Embodiment 5

In UMTS, scheduling information for broadcast information (SIB1-18) istransmitted using an MIB (Master Information Block), SB1 (SchedulingBlock 1) and SB2 (Scheduling Block 2). The MIB includes schedulinginformation for SIB1-18, SB1 and SB2, and SB1 and SB2 include schedulinginformation for SIB1-18.

A timing for transmitting the MIB is uniquely determined in UMTS. Byacquiring an MIB at the determined timing first, the mobile station canlearn scheduling information for the SIB, SB1 and SB2. By this means,the mobile station can learn which information can be acquired at whichtiming, for the first time. However, when SB1 or SB2 is included, themobile station does not know the scheduling information included in SB1or SB2 at this time, and so, by receiving SB1 or SB2, the mobile stationcan acquire all the scheduling information. SB1 and SB2 are optionalfunctions, and scheduling of all SIBs may be reported using the MIB.

Here, transmitting scheduling information in the LTE will be described.Also in the LTE, in the same way as in UMTS, the mobile station canlearn scheduling from information such as the MIB, that is, informationstored in the mobile station, but requires broadcast information thatcan be received. This information may be transmitted using fixedresources in the center frequency band (of a 1.25 MHz bandwidth), and byacquiring resources, the mobile station can obtain schedulinginformation for the broadcast information.

As described above, by acquiring the fixed resources in the centerfrequency band, the mobile station can obtain the schedulinginformation. However, the mobile station not capable of performingreception at 15 MHz or 20 MHz, may not be able to acquire the fixedresources in the center frequency band after having shifted toRRC_CONNECTED state. That is, the mobile station performs reception inthe center frequency band in RRC_IDLE state and can receive schedulinginformation for broadcast information. After this, when the mobilestation shifts to RRC_CONNECTED state, the mobile station cannot receivescheduling information for broadcast information. By this means, thereare the following two problems.

One problem is that required broadcast information also exists duringRRC_CONNECTED state and this information needs to be received every timethe information is updated. Whether the information is updated isreported using a value tag included in the MIB (or SB1 and SB2), and themobile station can learn whether the information is updated by receivingthe MIB. Therefore, mobile stations in RRC_CONNECTED state, which cannotacquire the MIB, can learn whether the information is changed, afteractually receiving data.

The other problem is that, although scheduling for broadcast informationmay not change so frequently, scheduling may change when the size of theinformation changes. In this case, the mobile station cannot obtainscheduling information for new broadcast information without acquiringthe MIB again.

In Embodiment 3, the arrangement of BCH1 in the frequency domain, whichis required by mobile stations in the connected mode, changes over time,and BCH2, which is required by mobile stations in idle mode, is fixed inthe center frequency band. Here, with regard to the detail oftransmission of broadcast information to mobile stations in connectedmode, various information is transmitted to the mobile stations. To bemore specific, in UMTS, the broadcast information is classified into theMIB, SB and SIB (the SIB includes various types such as SIB1, 2, 3, . .. , and 18). Further, as specified in detail in the “3GPP TS 25.331:Radio Resource Control; Protocol Specification,” mobile stations inconnected mode require a lot of information components.

FIG. 13 shows the configuration of base station 400 according to thepresent embodiment. In FIG. 13, components that are the same as those inEmbodiment 1 (FIG. 4) will be assigned the same reference numeralswithout further explanations.

As shown in FIG. 13, base station 400 has encoding sections 101-1 to101-M and modulating sections 102-1 to 102-M for blocks 1 to M of BCH1data. Here, blocks 1 to M are defined per unit of resources required asinput of data. BCH1 data is encoded and modulated per requiredresources. The modulated BCH1 data is outputted to transmission bandsetting section 401. Further, encoding and modulation may be the same ordifferent between resources.

Transmission band setting section 401 sets frequency band for actuallytransmitting the BCH1 data outputted from modulating sections 102-1 to102-M, and outputs the BCH1 data for which the frequency band is set, toIFFT section 106.

Therefore, to transmit these information to mobile stations in connectedmode, a lot of radio resources may be used. When the operation ofswitching per time the frequency band to which the BCH1 resourcesdescribed in Embodiment 3 are allocated (hereinafter “hopping”), iscombined, the BCH transmission method shown in FIG. 14 is possible.

In FIG. 14, four types of blocks of broadcast information are defined,and the blocks of the broadcast information are transmitted per (5 MHz)bandwidth in which the minimum capability mobile station can performcommunication. For example, when blocks of broadcast information are a,b, c and d, in the first frame, a is transmitted in the first 5 MHzband, b is transmitted in the second 5 MHz band from the top, c istransmitted in the third 5 MHz band from the top and d is transmitted inthe fourth 5 MHz band from the top. In the next frame, the blocks areshifted and transmitted. For example, b is transmitted in the first 5MHz band and c is transmitted in the second 5 MHz band from the top. Inthis example, as described above, four blocks a, b, c and d are definedand each have resources. Therefore, in the example of FIG. 13, M=4, and,for example, a=BCH1 data block 1 and b=BCH1 data block 2.

In this way, according to the present embodiment, the minimum capabilitymobile station can receive the broadcast information by performingreception at the (5 MHz) bandwidth in which the minimum capabilitymobile station performs communication, and the mobile station with highcapability can receive a plurality of broadcast information at the sametime, so that it is possible to reduce delay for receiving the broadcastinformation or reduce power consumption.

Although an example has been described with the present embodimentwhere, when BCH1 resources are hopped in the frequency domain per time,radio resources for different BCH1 perform the same hopping operation,it is also possible to perform the hopping operation shown in FIG. 15.To be more specific, when there are BCH1-1 and BCH1-2, BCH1-1 may behopped every frame, and BCH1-2 may be hopped every two frames.

Further, BCH1 may be defined as the combination of a plurality of radioresources. That is, as shown in FIG. 16, BCH1 actually has threeresources in the first frame, the first resource in the three resourcesis used only once per each of four frames, the second resource isensured every two frames, and the last resource is ensured every frame.In this case, the aggregate of these is defined as BCH1 and may behopped in the frequency domain. In the case of FIG. 16, M=1 and there isonly one resource unit. However, there may be a plurality of suchcombinations of radio resources, and, in that case, M becomes plural.

Further, although a case has been described with the present embodimentwhere broadcast information for use in idle mode is all transmitted in1.25 MHz of the center frequency band, it is also possible to performtransmission using other resources. To be more specific, as shown inFIG. 17, resource blocks for transmitting the broadcast information foruse in idle mode is prepared other than 1.25 MHz of the center frequencyband. All mobile stations in idle mode need to be able to receive thisinformation, and so the frequency band to be used is limited to thebandwidth (here, 5 MHz) in which the minimum capability mobile stationin the center frequency band can perform communication.

Embodiment 6

Although how radio resources are allocated for a lot of information thathave to be transmitted to mobile stations in connected mode, has beendescribed with Embodiment 5, information relating to scheduling ofinformation allocated to radio resources will be described in Embodiment6 of the present invention. Here, an MIB and SIB1-3 are assumed to bebroadcast information for mobile stations in idle mode, and an SB andSIB4-8 are assumed to be broadcast information for mobile stations inconnected mode.

As described above, in UMTS, scheduling information for broadcastinformation (SIB) is transmitted using the MIB or SB1 and SB2. However,when this scheduling information is transmitted in the center frequencyband, a problem arises that mobile stations in connected mode cannotreceive new scheduling information. To solve this problem, schedulinginformation for the broadcast information transmitted in the centerfrequency band and scheduling information for the SB transmitted inbands other than the center frequency band, are transmitted using theMIB.

Here, the SB is transmitted per (5 MHz) bandwidth in which the minimumcapability mobile station can perform communication so that the minimumcapability mobile station can receive the SB. Scheduling information forbroadcast information mobile stations in RRC_CONNECTED state require isreported using the SB. FIG. 18 is its conceptual diagram. Here, a caseis shown for ease of explanation, where the bandwidth in which theminimum capability mobile station can perform communication is 10 MHzinstead of 5 MHz and SIB1-3 exists as broadcast information for use inidle mode, and SIB4-8 exists as broadcast information for use inconnected mode. Here, the MIB includes broadcast information SIB1-3 formobile stations in idle mode and scheduling information for the SB. Onthe other hand, the SB includes scheduling information for broadcastinformation SIB4-8 for use in connected mode. Therefore, a mobilestation in idle mode can obtain scheduling information for SB includingscheduling information for broadcast information to be received when themobile station shifts to connected mode, in addition to schedulinginformation for SIB1-3 the mobile station requires. Further, a mobilestation in connected mode receives the SB based on schedulinginformation for the SB received in idle mode. The mobile station obtainsscheduling information for SIB4-8, which is broadcast information foruse in connected mode, thereby receiving SIB4-8.

FIG. 19 shows the configuration of base station 500 according to thepresent embodiment. In FIG. 19, components that are the same as those inEmbodiment 5 (FIG. 13) will be assigned the same reference numeralswithout further explanations.

In FIG. 19, broadcast information controlling section 501 controls, forexample, how often broadcast information is transmitted, transmissiontiming of the broadcast information and resource information (resourceamount) required for transmitting the broadcast information. Informationfor mobile stations in connected mode is outputted to connected-modescheduling information creating section 502 as control information, andinformation for mobile stations in idle mode is outputted to idle-modescheduling information creating section 503. Further, broadcastinformation controlling section 501 also controls transmission bandsetting section 401 and controls transmission band for broadcastinformation.

Connected-mode scheduling information creating section 502 createsscheduling information for broadcast information to be transmitted tomobile stations in connected mode. This scheduling informationcorresponds to content of the above-described SB. This result isoutputted to connected-mode broadcast information message creatingsection 505.

Idle-mode scheduling information creating section 503 creates schedulinginformation for broadcast information to be transmitted to mobilestations in idle mode. This information is included in content of theabove-described MIB. This result is transmitted to idle-mode broadcastinformation message creating section 506.

Broadcast information data section 504 processes broadcast informationdata and outputs broadcast information for mobile stations in connectedmode to connected-mode broadcast information message creating section505 and outputs broadcast information for mobile stations in idle modeto idle-mode broadcast information message creating section 506.

Connected-mode broadcast information message creating section 505creates broadcast information messages for mobile stations in connectedmode per frequency band and outputs the messages to encoding sections101-1 to 101-M as BCH1 data.

Idle-mode broadcast information message creating section 506 createsbroadcast information messages for mobile stations in idle mode andoutputs the messages to encoding section 301 as BCH2 data.

Next, the operation of the base station shown in FIG. 19 will bedescribed.

Broadcast information controlling section 501 determines information forcontrolling the broadcast information. Here, the information forcontrolling the broadcast information includes types of broadcastinformation, size for each type of broadcast information, transmissiontiming for each type of broadcast information. Broadcast informationcontrolling section 501 picks up broadcast information that should betransmitted using this cell, for mobile stations in connected mode, fromthe type of broadcast information, and outputs their sizes, transmissiontimings and the like to connected-mode scheduling information creatingsection 502 per type of broadcast information. In the same way,broadcast information controlling section 501 picks up broadcastinformation that should be transmitted using this cell, for mobilestations in idle mode, from the type of broadcast information, andoutputs their sizes, transmission timings and the like to idle-modescheduling information creating section 503 per type of broadcastinformation.

Connected-mode scheduling information creating section 502 and idle-modescheduling information creating section 503 create schedulinginformation based on the information outputted from broadcastinformation controlling section 501. Examples of scheduling informationinclude transmission timing for each type of broadcast information,transmission cycle and radio resource information required fortransmitting broadcast information. This result is outputted fromconnected-mode scheduling information creating section 502 toconnected-mode broadcast information message creating section 505, andoutputted from idle-mode scheduling information creating section 503 toidle-mode broadcast information message creating section 506. Here,scheduling information for use in idle mode is transmitted using theMIB, and there is one piece of scheduling information for use in idlemode. When both MIB and SB are used to transmit scheduling informationfor use in idle mode, there are a plurality of pieces of schedulinginformation for use in idle mode. Further, different schedulinginformation for use in connected mode may be transmitted per frequencyband. In that case, it is necessary to change scheduling informationdepending on which frequency band is used to transmit schedulinginformation, and so it is necessary to create scheduling informationtaking into consideration to which frequency band scheduling informationis transmitted.

Broadcast information data section 504 manages data included inbroadcast information, outputs broadcast information for mobile stationsin connected mode to connected-mode broadcast information messagecreating section 505, and outputs broadcast information for mobilestations in idle mode to idle-mode broadcast information messagecreating section 506. The content of this broadcast information may beset by the higher layer, set manually or set using other methods, butany method is possible.

Connected-mode broadcast information message creating section 505creates broadcast information messages using broadcast information datafor mobile stations in connected mode outputted from broadcastinformation data section 504, and the scheduling information outputtedfrom connected-mode scheduling information creating section 502. In theexample of FIG. 18, SB and SIB4-8 are generated. The generated broadcastinformation messages are outputted to a section to which the messagesshould be transmitted, among encoding sections 101-1 to 101-M. In thecase of the first frame in the example of FIG. 18, SIB6 is transmittedto the higher 10 MHz and SB is transmitted to the lower 10 MHz. WhenSIB6 is transmitted using BCH data block 1 and SB is transmitted usingBCH data block M, SIB6 is transmitted to encoding section 101-1 and SBis transmitted to encoding section 101-M. This operation is performedevery timing broadcast information is transmitted.

Further, data outputted to encoding sections 101-1 to 101-M is not thesame, and, in the example of FIG. 18, in the first frame, SB isoutputted to encoding section 101-1 and SIB6 is outputted to encodingsection 101-M. The encoded and modulated signal is outputted totransmission band setting section 401.

Transmission band setting section 401 is controlled by broadcastinformation controlling section 501. To be more specific, broadcastinformation controlling section 501 controls transmission band settingsection 401 as to which broadcast information is transmitted using whichfrequency band.

Idle-mode broadcast information message creating section 506 createsbroadcast information messages from broadcast information data formobile stations in idle mode outputted from broadcast information datasection 504 and the scheduling information outputted from idle-modescheduling information creating section 503. In the example of FIG. 18,an MIB and SIB1-3 are generated.

In this way, according to the present embodiment, it is possible to hopin the frequency domain, the broadcast information to be transmitted tomobile stations in connected mode. As a result, compared to the casewhere the same broadcast information is transmitted per frequency band,the mobile station that can receive 20 MHz band, can suppress receptiondelay of broadcast information and receive broadcast information.

In UMTS, as scheduling information for broadcast information,information showing the position of the SIB (information correspondingto a frame number), how often information is transmitted (that is,information as to every how many frames information is transmitted) andinformation whether the SIB is arranged across frames (whether the SIBis divided into segmentations). In the LTE, it is also possible to useinformation similar to that in UMTS or supplementary information (suchas subcarrier information) to be added to similar information, asscheduling information. Scheduling may be performed using otherinformation.

There are several patterns in transmission of the above-describedsubcarrier information. The LTE manages a plurality of subcarriers asone radio resource. By assigning an index to this radio resource, it ispossible to report in a simple manner which radio resource is used toperform transmission. However, there are a plurality of patterns inallocation of this radio resource, and, depending on the pattern to beused, different subcarriers may be actually allocated even for the sameindex. This pattern information needs to be transmitted in the centerfrequency band to perform scheduling of the SB. Therefore, the mobilestation may use the pattern received in idle mode as is. Further, themobile station may perform transmission again using the pattern for usein connected mode. By this means, mobile stations in connected mode canlearn the allocation pattern of the radio resource without receiving thecenter frequency band. Further, the allocation pattern may be changedper TTI. In this case, mobile stations can learn the final allocationpattern based on L1 and L2 control signaling.

In the present embodiment, the SB is transmitted per frequency bandsupported by the minimum capability mobile station. The content of thisSB can be changed between frequency bands or can be made exactly thesame. When the content of this SB is made exactly the same, informationshowing the position of the SIB becomes the same between frequencybands, and so it is not possible to provide the advantage of the presentinvention. Therefore, as a reference for the position of the SB, theposition of the SIB may be determined. That is, although scheduling isnormally determined using SFN (System Frame Number), the position of theSIB is determined by shifting the position by the amount correspondingto the position of the SB. To describe this in detail using setting inUMTS, the scheduling information for SB specified using the MIB isassumed to be set such that information showing the position of theSB=the fourth frame and transmission is performed at a frequency ofevery 32 frames, and the scheduling information of the SB specifiedusing the SB is assumed to be set such that information showing theposition of SIB4=the sixth frame and transmission is performed at afrequency of every 64 frames. In this case, the SB is transmitted when“SFN value mod 32” is 4. SIB4 is normally transmitted when “SFN valuemod 64” is 6. However, given an addition of 4 which shows the positionof the SB, the SB is transmitted when “SFN value mod 64” is 10. In thiscase, as long as the position of the SB is shifted per frequency band,even if the content of the SB is the same, the same information is nottransmitted at the same time.

Further, it is also possible to determine offset of each frequency bandin advance. To be more specific, when there are four frequency bands,numbers 0 to 3 are assigned to the frequency bands. By multiplyingoffset values by frequency band numbers at the mobile station, it ispossible to receive the scheduling information in the frequency band towhich the mobile station connects. This offset information may beincluded in the MIB or included in the SB. Further, this offsetinformation may be content that is fixed in the system. In this case, itis possible to perform the operation of making only the position of theSB the same between frequency bands.

Further, as shown in FIG. 18, SIBs may be arranged in the same orderbetween higher and lower frequency bands or may be arranged in differentorder. Further, when the content is the same, a mobile station with highcapability only has to receive the SB and show the difference betweenscheduling in different frequency bands to report the scheduling indifferent frequency bands. Further, when the order is different, it isnecessary to include all the scheduling information for differentfrequency bands.

As described above, by making the content of the SB common between thefrequency bands or specifying the scheduling information of otherfrequency bands, the mobile station receiving a specific frequency bandcan learn scheduling information for other frequency bands. By thismeans, when there is information required at the mobile station side, itis possible to provide the advantage of making it possible to receiveinformation from other frequency bands by changing the frequency band.To be more specific, when data is not transmitted to the mobile stationfor a while and does not have to be transmitted, if the mobile stationlearns that there is required broadcast information and can obtainbroadcast information faster by shifting to other frequency bands, themobile station changes the frequency band.

Although with the present embodiment scheduling information for SB (theposition information for SB included in MIB) is assumed to be stationaryto some extent, it is also possible to support a case where thescheduling information is changed. To be more specific, it is possibleto support mobile stations in idle mode only by updating the content ofthe MIB, and it is only necessary to report scheduling information forthe SB to mobile stations in connected mode using a dedicated channel.Further, by transmitting the value tag of the MIB to mobile stations inconnected mode in the same way as system information change indicationused in UMTS, it is possible to command the mobile stations to acquirethe MIB again.

Embodiment 7

Although a case has been mainly described with Embodiment 6 wherebroadcast information is transmitted in the same order per frequencyband the minimum capability mobile station supports, a case will bedescribed with Embodiment 7 of the present invention where furtheroptimization is achieved based on the operation for the reception ofinformation the mobile station requires.

As described in Embodiment 5, there are a lot of SIBs. Here, when themobile station performs RACH procedure, channel setting information forcommon channels and information such as the amount of uplinkinterference, are required, and these may be transmitted in differentblocks. In this case, the mobile station can start RACH procedure onlyafter receiving these two pieces of information. Therefore, it isnecessary to receive these two pieces of information at the same time orat timings as close as possible. FIG. 20 is a conceptual diagram oftransmission of the broadcast information that realizes this.

Here, SIB5 and SIB6 are assumed to be, for example, an information setrequired for the RACH procedure. At this time, SIB5 and SIB6 aretransmitted in the higher frequency band and the lower frequency band,respectively, in second frame. The mobile station having capability ofperforming communication at 20 MHz can acquire all the information atthis time. Next, in third frame, SIB6 and SIB5 are transmitted in thehigher frequency band and the lower frequency band, respectively. Atthis time, it is possible to obtain information even if the mobilestation capable of performing communication at 10 MHz connects to one ofthe frequency bands. By adopting this transmission method, requiredinformation can be obtained in one frame or in a plurality ofconsecutive frames, so that it is possible to reduce delay.

FIG. 21 shows the configuration of base station 600 according to thepresent embodiment. In FIG. 21, broadcast information associatingsection 601 manages related information of different types of broadcastinformation and outputs the information to broadcast informationcontrolling section 501.

Next, the operation of the base station shown in FIG. 21 will bedescribed.

Broadcast information associating section 601 manages the relatedinformation of different types of broadcast information as describedabove. Here, the related information includes the type of the broadcastinformation required for performing RACH procedure and the type of thebroadcast information required for performing handover. In the exampleof FIG. 20, SIB5 and SIB6 are managed as a related pair, and SIB7 andSIB8 are managed as a related pair. This information is outputted frombroadcast information associating section 601 to broadcast informationcontrolling section 501. From this information, broadcast informationcontrolling section 501 performs scheduling to transmit the relatedbroadcast information at the same timing in different frequency bandsand performs scheduling so that this information continues in the timedomain.

Although RACH procedure has been described as an example with thepresent embodiment, the present invention can be implemented in the sameway using other processing (such as handover processing).

With this scheduling reporting method, it is also possible to make thevalues of the SB in different frequency bands the same. To be morespecific, inversion flags are assigned to SIB5 and SIB6, and SIB5 andSIB6 are inverted in a specific frequency band. By such processing, itis possible to learn scheduling information without acquiring the SB indifferent frequency bands, and, when the mobile station fails to receiverequired broadcast information, it is possible to shift the frequencyvoluntarily and perform reception processing.

With regard to the related pair in the broadcast information, specificinformation components may relate to a plurality of processing. Forexample, when the broadcast information required for RACH procedure andthe broadcast information required for handover are common in part,priority may be assigned to show which should be prioritized. Thispriority information is managed by broadcast information associatingsection 601 and outputted to broadcast information controlling section501, so that it is possible to perform scheduling of broadcastinformation according to priority.

It is also possible to include MBMS data, that is, multicast andbroadcast data, as broadcast information in all the above-describedembodiments of the invention. It is also possible to combine two or moreembodiments of all the above-described embodiments of the presentinvention.

Embodiments of the present invention have been described above.

Although a 5 MHz mobile station has been described as the minimumcapability mobile station with the above-described embodiments, theminimum capability mobile station may be mobile stations other than the5 MHz mobile station.

Further, when there is a mobile station having a radio section capableof communicating in a bandwidth of 20 MHz and a baseband section onlycapable of communicating in a bandwidth of 5 MHz, the present inventioncan be applied supposing that the minimum communication capability is 5MHz. Further, when there is a mobile station capable of performingreception in a bandwidth of 20 MHz but only capable of performingtransmission in a bandwidth of 5 MHz, the present invention can beapplied in the same way supposing that the minimum communicationcapability is 5 MHz.

Further, although a case has been described with the above-describedembodiments where bands FB1 to FB4 continue and are utilized as oneband, the present invention is not limited to this. For example, FB1 maybe operated in 800 MHz frequency band, FB2 may be operated in 1.5 MHzfrequency band, or FB1 and FB2 may be discontinuous different bands.

Further, the content of BCH data may be made different between frequencybands.

Further, the base station, mobile station, subcarrier, cyclic prefix,subframe may be referred to as “Node B,” “UE,” “tone,” “guard interval,”and “time slot” or simply “slot,” respectively.

Further, although a case where the present invention is implemented byhardware has been explained as an example with the above embodiments,the present invention can also be implemented by software.

Each function block used to explain the above-described embodiments maybe typically implemented as an LSI constituted by an integrated circuit.These may be individual chips or may partially or totally contained on asingle chip.

Furthermore, here, each function block is described as an LSI, but thismay also be referred to as “IC”, “system LSI”, “super LSI”, “ultra LSI”depending on differing extents of integration.

Further, the method of circuit integration is not limited to LSI's, andimplementation using dedicated circuitry or general purpose processorsis also possible. After LSI manufacture, utilization of a programmableFPGA (Field Programmable Gate Array) or a reconfigurable processor inwhich connections and settings of circuit cells within an LSI can bereconfigured is also possible.

Further, if integrated circuit technology comes out to replace LSI's asa result of the development of semiconductor technology or a derivativeother technology, it is naturally also possible to carry out functionblock integration using this technology. Application of biotechnology isalso possible.

The disclosures of Japanese Patent Application No. 2006-004157, filed onJan. 11, 2006, and Japanese Patent Application No. 2006-275639, filed onOct. 6, 2006, including the specifications, drawings and abstracts, areincorporated herein by reference in their entirety.

INDUSTRIAL APPLICABILITY

The present invention is suitable for use as a base station, and thelike, used in a mobile communication system.

1. A radio communication base station apparatus that transmits amulticarrier signal comprised of a plurality of subcarriers and thatcommunicates with a plurality of radio communication mobile stationapparatuses, which have respectively different capabilities forperforming communication in different bandwidths, the radiocommunication base station apparatus comprising: a setting section thatsets a transmission band for a broadcast channel signal, which isaddressed to all of the plurality of radio communication mobile stationapparatuses, to one of a plurality of first frequency bands in a secondfrequency band, the second frequency band being divided into theplurality of first frequency bands, each of the first frequency bandshaving a minimum bandwidth of the different bandwidths; a generatingsection that generates the multicarrier signal by mapping the broadcastchannel signal on a subcarrier in the transmission band set by thesetting section out of the plurality of subcarriers; and a transmittingsection that transmits the multicarrier signal to the radiocommunication mobile station apparatuses, wherein the setting sectionchanges over time the first frequency band which is set as thetransmission band in the second frequency band.
 2. The radiocommunication base station apparatus according to claim 1, wherein thesetting section changes over time periodically the first frequency bandwhich is set as the transmission band in the second frequency band. 3.The radio communication base station apparatus according to claim 1,wherein the generating section further maps a synchronization channelsignal that reports which one of the plurality of first frequency bandsthe transmission band is set to by the setting section, on apredetermined subcarrier out of the plurality of subcarriers.
 4. Theradio communication base station apparatus according to claim 3, whereinthe transmitting section transmits a multicarrier signal comprising thebroadcast channel signal at a second transmission timing delayed by anamount of time which a radio communication mobile station apparatustakes to switch frequency, from a first transmission timing for amulticarrier signal comprising the synchronization channel signal. 5.The radio communication base station apparatus according to claim 1,wherein the setting section sets a transmission band for a firstbroadcast channel signal comprising information required by a firstradio communication mobile station apparatus out of the first radiocommunication mobile station apparatus communicating user data and asecond radio communication mobile station apparatus not communicatingthe user data.
 6. The radio communication base station apparatusaccording to claim 5, wherein the generating section maps a secondbroadcast channel signal comprising information required by the secondradio communication mobile station apparatus on a predeterminedsubcarrier out of the plurality of subcarriers.
 7. The radiocommunication base station apparatus according to claim 5, wherein: thesetting section sets transmission bands for different first broadcastchannel signals to the plurality of first frequency bands; and thetransmitting section transmits a multicarrier signal comprising thedifferent first broadcast channel signals at the same transmissiontiming.
 8. The radio communication base station apparatus according toclaim 1, wherein the setting section sets the transmission band to oneof the first frequency bands which is different from another of thefirst frequency bands in which another transmission band is set byanother radio communication base station apparatus of an adjacent cell.9. The radio communication base station apparatus according to claim 1,wherein the setting section sets scheduling information of a secondbroadcast channel signal and scheduling information of a schedulingblock to a center frequency band of a second frequency band and sets ascheduling block that reports scheduling information of a firstbroadcast channel signal to the first frequency band.
 10. The radiocommunication base station apparatus according to claim 9, furthercomprising an associating section that associates different broadcastchannel signals, wherein the setting section sets the associateddifferent broadcast channel signals to the plurality of first frequencybands.
 11. A transmission band setting method for setting a transmissionband for a broadcast channel signal addressed to a plurality of radiocommunication mobile station apparatuses, which have respectivelydifferent capabilities for performing communication in differentbandwidths, the method comprising: setting the transmission band for thebroadcast channel signal to one of a plurality of first frequency bandsin a second frequency band, the second frequency band being divided intothe plurality of first frequency bands, each of the first frequencybands having a minimum bandwidth of the different bandwidths; andchanging over time the first frequency band which is set by the settingas the transmission band in the second frequency band.